Haematologica (Sep 2020)

Replication stress signaling is a therapeutic target in myelodysplastic syndromes with splicing factor mutations

  • Johanna Flach,
  • Johann-Christoph Jann,
  • Antje Knaflic,
  • Vladimir Riabov,
  • Alexander Streuer,
  • Eva Altrock,
  • Qingyu Xu,
  • Nanni Schmitt,
  • Julia Obländer,
  • Verena Nowak,
  • Justine Danner,
  • Arwin Mehralivand,
  • Franziska Hofmann,
  • Iris Palme,
  • Ahmed Jawhar,
  • Patrick Wuchter,
  • Georgia Metzgeroth,
  • Florian Nolte,
  • Wolf-Karsten Hofmann,
  • Daniel Nowak

DOI
https://doi.org/10.3324/haematol.2020.254193
Journal volume & issue
Vol. 106, no. 11

Abstract

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Somatic mutations in genes coding for splicing factors, e.g., SF3B1, U2AF1, SRSF2, and others are found in approximately 50% of patients with myelodysplastic syndromes (MDS). These mutations have been predicted to frequently occur early in the mutational hierarchy of the disease, therefore, making them particularly attractive potential therapeutic targets. Recent studies in cell lines engineered to carry splicing factor mutations have revealed a strong association with elevated levels of DNA:RNA intermediates (R-loops) and a dependency on proper ATR function. However, data confirming this hypothesis in a representative cohort of primary MDS patient samples have so far been missing. Using CD34+ cells isolated from MDS patients with and without splicing factor mutations as well as healthy controls we show that splicing factor mutation- associated R-loops lead to elevated levels of replication stress and ATR pathway activation. Moreover, splicing factor mutated CD34+ cells are more susceptible to pharmacological inhibition of ATR resulting in elevated levels of DNA damage, cell cycle blockade, and cell death. This can be enhanced by combination treatment with the low-dose splicing modulatory compound Pladienolide B. We further confirm the direct association between R-loops and ATR sensitivity and the presence of a splicing factor mutation using lentiviral overexpression of wild-type and mutant SRSF2 P95H in cord blood CD34+ cells. Collectively, our results from n=53 MDS patients identify replication stress and associated ATR signaling to be critical pathophysiological mechanisms in primary MDS CD34+ cells carrying splicing factor mutations, and provide a preclinical rationale for targeting ATR signaling in these patients.